Integration of bioelectricity generation from algal biophotovoltaic (BPV) devices with remediation of palm oil mill effluent (POME) as substrate for algal growth

The exploitation of renewable energy sources for delivering carbon neutral or carbon negative solutions has to be achieved through strategies involving the removal of CO2 from the atmosphere. Agro-industries like palm oil processing are important sources of energy but are also generators of large volumes of wastewater, causing pollution problems. Bioremediation of these effluents utilizing microalgae has shown promising results. In the present study, we developed an algal-biophotovoltaic device to generate direct bioelectricity from photosynthesis while using palm oil mill effluent (POME) as substrate for microalgal growth. Nine microalgal strains from the University of Malaya Algae Culture Collection (UMACC) were cultured using POME in four different concentrations (50%, 25%, 10%, and 5%) for 12 days. Chlorella vulgaris Beijerinck UMACC 051 showed the highest specific growth rate (1.32 d(-1)) and Chlorella UMACC 301 showed high photosynthetic performance (Alpha = 0.88) when grown in 5% POMEBBM medium. Three selected microalgal strains were grown in the control medium (Bold's Basal Medium) and 5% POME-BBM medium in an annular biophotovoltaic device. The maximum power density (0.45 mW m(-2)) obtained from Chlorella UMACC 313 in the POME-BBM medium, was 15% higher than the power density generated when the microalgal cells were grown in the control medium (0.38 mW m(-2)). When Chlorella UMACC 313 was cultured in a 4L round integrated fuel cell-photobioreactor prototype device, the maximum power density obtained was 0.28 mW m(-2). The reductions in NO3-N, o-PO43-, NH3-N and COD were 54.92%, 29.41%, 80.75 and 60.09% respectively. A final biomass of 810 mg L-1 was obtained after 12 days' growth and the CO2 fixation rate was 76.82 mgCO(2) L-1 d(-1). This BPV system represents a multi-functional system that generates low power density while providing wastewater bioremediation and carbon removal. This has potential as a sustainable environment-friendly carbon-neutral or carbon-reducing energy generation system. (C) 2020 Elsevier B.V. All rights reserved.

Automated summary

This study focused on utilizing microalgae for bioremediation of palm oil mill effluent (POME) and developing an algal-biophotovoltaic device to generate bioelectricity. Results showed that culturing microalgae in POME improved growth rate and photosynthetic performance.